Air handler power distribution system

Information

  • Patent Grant
  • 6647203
  • Patent Number
    6,647,203
  • Date Filed
    Friday, August 6, 1999
    25 years ago
  • Date Issued
    Tuesday, November 11, 2003
    21 years ago
Abstract
A power distribution system for an air handler is reconfigureable by way of selectively connectable plug-in connectors. The air handler includes a blower associated with a first plug-in connector that is selectively connectable to a second plug-in connector of a heater and a third plug-in connector of an electric air cleaner. If the air handler includes a heater but not the electric air cleaner, then the blower connector plugs into the heater connector. If the air handler includes an electric air cleaner but not a heater, then the blower plugs into the connector of the air cleaner. And if the air handler includes both a heater and an electric air cleaner, then a three-way electrical connector couples the blower to both the heater and the air cleaner.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The subject invention generally pertains to an air handler and more specifically to an air handler connected to a reconfigureable electrical distribution system.




2. Description of Related Art




Air handlers typically condition the air of a comfort zone, such as a room or area within a building, and can assume a variety of configurations. Many air handlers include a fan or blower to move the air across a heat exchanger, such as an evaporator or condenser of a heat pump or some other refrigeration system. They can also include a variety of other components or accessories, such as an electrostatic air cleaner and/or supplemental electric heaters. Unfortunately, the variety of configurations can create a problem for an electrician installing the equipment.




For example, when an electrostatic air cleaner is to be added to an air handler having an electric heater, a 115 or 230-volt outlet may not be available for the air cleaner. Since installing such an outlet adds to the time and cost of the air cleaner's installation, an electrician may consider wiring the air cleaner in parallel with the 115 or 230-volt electric heater. However, such an approach often violates national and local electrical codes, as the current draw of a heater is usually much higher than that of an air cleaner. Consequently, an air cleaner's lighter gage wiring may be inadequately protected against current overload (e.g., a short circuit) when it is connected in parallel with a heater's heavier gage wiring. This is especially true when the heavier wiring is protected by a circuit breaker that is appropriate for the heavier wiring but oversized for the lighter wiring.




SUMMARY OF THE INVENTION




To facilitate the installation of air handlers of various configurations, it is an object of the invention to provide a power distribution system that is reconfigureable by way of selectively connectable plug-in connectors.




Another object of the invention is to safely connect lighter gage wiring of an air handler accessory in parallel with an electric heater having heavier gage wiring.




Another object is to provide a three-way electrical connector that reconfigures an air handler to accept various accessories.




Yet another object is to provide a reconfigureable plug-in connector that conveys both control voltage and higher power voltage.




A further object of the invention is to effectively protect both lighter and heavier gage wiring with a common circuit breaker.




A still further object is to avoid the time and cost of installing an additional electrical outlet dedicated to power an accessory of an air handler.




These and other objects of the invention are provided by an air handler that includes a blower associated with a first plug-in connector that is selectively connectable to a second plug-in connector of a heater and a third plug-in connector of an electric accessory to selectively reconfigure the air handler.











BRIEF DESCRIPTIONS OF THE DRAWINGS





FIG. 1

is a wiring schematic of an embodiment of the invention showing an air handler in one configuration.





FIG. 2

is a wiring schematic of an embodiment of the invention showing an air handler in a second configuration.





FIG. 3

is a wiring schematic of an embodiment of the invention showing an air handler in a third configuration.





FIG. 4

is a wiring schematic of an embodiment of the invention showing an air handler in a fourth configuration.





FIG. 5

is a wiring schematic of an embodiment of the invention showing an air handler in a fifth configuration.











DESCRIPTION OF THE PREFERRED EMBODIMENT




An air handler, schematically illustrated in

FIG. 1

, includes a three-way connector


10


that electrically interconnects a blower


12


, a heater assembly


14


, an electric air cleaner


16


, and an electrical panel


18


. Blower


12


draws return air from a comfort zone and through cleaner


16


that electrostatically removes dust and other airborne particles. Blower


12


discharges the air across one or more heaters, such as heaters


20


,


22


and


24


, to provide heated supply air to the comfort zone when needed. Arrows


26


denote the general direction of airflow. Typically the blower


12


and the heater assembly


14


share a common housing


25


. The air cleaner


16


is preferably connected upstream of the housing


25


so that air flows through the air cleaner


16


into the blower


12


, and across the heaters


20


,


22


,


24


. In some embodiments, the air handler also includes a refrigeration system, such as a heat pump that also conditions the temperature and/or humidity of the comfort zone. In such embodiments, the heat pump provides the primary cooling or heating, while heaters


20


,


22


and


24


supplement heating as needed. In response to sensing the temperature and/or humidity of the comfort zone, a conventional thermostat


28


controls the operation of heater assembly


14


and blower


12


, and may further control the operation of the heat pump, if present.




In the embodiment of

FIG. 1

, an electrical supply


30


(e.g., power voltage of 230 VAC) is applied across supply leads


32


and


34


to power the air handler. Two current interrupters


36


(e.g., a 30-amp circuit breaker or fuse), a set of normally open relay contacts


38


and a normally closed temperature limit switch


40


are connected electrically in series with heater


20


. This allows electrical supply


30


to energize heater


20


when contacts


38


and limit switch


40


are closed. Under normal operation, temperature limit switch


40


remains closed and only opens upon sensing an abnormally high temperature brought on by, for example, insufficient airflow across heater


20


. A relatively heavy wire


42


(e.g., 12-gage wire) provides the series connection of the heater-related components. Similarly, two more current interrupters


44


(e.g., 60-amp circuit breaker or fuse), a set of normally open relay contacts


46


and a normally closed temperature limit switch


48


(similar or identical to switch


40


) are connected electrically in series with heater


22


. Supply


30


energizes heater


22


when contacts


46


and limit switch


48


are closed. Interconnecting wire


50


is similar to that of wire


42


. A set of relay contacts


52


and a temperature limit switch


54


(similar or identical to switch


40


) couple heater


24


electrically in parallel with heater


22


and in series with breakers


44


. Thus, breakers


36


protect wiring


42


, while breakers


44


protect wiring


50


and also protect interconnecting 12-gage wire


56


associated with heater


24


. Electrical power leads


58


and


60


are wired to a plug-in connector


62


(e.g., a socket 19-09-2061 w/02-09-2101 by Molex of Lisle, Ill.). An additional three leads


64


,


66


and


68


connect socket


62


to a 24-volt (control voltage) relay coil


70


associated with contacts


38


and


46


, and a similar relay coil


72


associated with contacts


52


.




Three-way connector


10


, comprising plug-in connectors


74


,


76


and


78


, plugs into socket


62


by way of connector


74


(e.g., a Molex plug 19-09-1061 w/02-09-1102). Connectors


62


and


74


connect power voltage leads


58


and


60


to air cleaner


16


by way of wires


80


, a connector


78


(e.g., a Molex plug 19-09-1061 w/02-09-1102), a mating plug-in connector


82


(e.g., a Molex socket 19-09-2061 w/02-09-2101), wires


84


, wire nuts


86


, and an air cleaner power cord


88


. Connectors


62


and


74


also connect leads


60


,


58


,


64


,


66


and


68


to wires


90


,


92


,


94


,


96


and


98


respectively by way of wires


100


, a plug-in connector


76


(e.g., a Molex socket 19-09-2061 w/02-09-2101), and a mating plug-in connector


102


(e.g., a Molex plug 19-09-1061 w/02-09-1102). In this embodiment, wires


90


,


92


,


94


,


96


and


98


feed into panel


18


.




Within panel


18


, wires


90


and


92


apply power voltage to the primary windings of a transformer


104


to provide 24 VAC control voltage across wire


94


and a wire


106


. Wire


106


conveys the control voltage onto thermostat


28


. Since there are a wide variety of thermostats know to those skilled in the art, thermostat


28


is schematically illustrated to include a blower switch


108


and two temperature switches


110


and


112


, all of which receive control voltage from wire


106


. Switches


110


and


112


both close in response to the temperature of the comfort zone dropping to a set point, but each at a slightly different set point. Blower switch


108


closes in response to a demand for airflow, e.g., whenever switch


110


or


112


calls for heat. Blower switch


108


closing energizes a coil


114


of a blower relay


116


to close its contacts


118


and


120


. Contacts


120


energize blower


112


, while contacts


118


enable switches


110


and


112


to energize their respective coils


72


and


70


. Switch


110


closing energizes coil


72


through leads


64


and


68


to actuate contacts


52


, which turns on heater


24


. Switch


112


closing energizes coil


70


through leads


64


and


66


to actuate contacts


38


and


46


. Contacts


38


and


46


turn on heaters


20


and


22


respectively.




In many cases, wiring a low wattage component with light gage wire in parallel with a higher wattage component having heavier gage wire is considered poor wiring practice and often violates electrical codes. However, a unique opportunity presents itself with an air handler having several high-wattage heaters and a low wattage air cleaner connected as shown in FIG.


1


. For air handlers, some electrical codes restrict the maximum allowable current draw of heaters to about 48 amps when the heater wiring is protected by just one pair of circuit breakers. For heat requirements above 48 amps, multiple heaters are wired in parallel to each other to create several parallel circuits each wired with, for example, 12-gage wiring (to conduct up to 48 amps). And each parallel circuit can be protected by a pair of standard-sized 30-amp or 60-amp breakers, depending on the size of the heater or heaters. However, 18-gage wiring can also readily trip a 60-amp breaker. Thus, lighter 18-gage wire can safely connect an appropriately sized, relatively low wattage air cleaner in parallel with a heater, provided the air cleaner is wired in series with one pair of breakers that protects the heater's heavier gage wiring. For example, one pair of breakers can protect both the 12-gage wire leading to a heater and a lighter 18-gage wire feeding an air cleaner.




For the exemplary embodiment of

FIG. 1

, air cleaner power cord


88


is 16-gage wiring that electrically connects air cleaner


16


in parallel with heater


24


and in series with breakers


44


. Heaters


20


,


22


and


24


each draw about twenty amps, and breaker


44


is rated at sixty amps. Thus, breaker


44


protects the 12-gage wiring


50


and


56


of respective heaters


22


and


24


as well protects the 16-gage wiring of power cord


88


.




The air handler of

FIG. 1

can also be reconfigured as shown in FIG.


2


. When air cleaner


16


is omitted, blower connector


102


plugs directly into heater socket


62


, and the three-way connector


10


and the air cleaner power cord


88


are not required. Socket


82


and wires


84


can be removed or left unused as shown. The operation of blower


12


, heater assembly


14


and thermostat


88


remains basically the same as that of the configuration of FIG.


1


.




In another configuration, shown in

FIG. 3

, the air handler includes air cleaner


16


but does not include heater assembly


14


. In this example, blower connector


102


plugs directly into socket


82


, and electrical supply


30


delivers power voltage directly to the air cleaner power cord


88


and wires


84


at wire nuts


86


. Wires


84


deliver the power voltage to wires


90


and


92


to energize blower


12


and transformer


104


.




In yet another configuration, shown in

FIG. 4

, the air handler has neither heater assembly


14


nor air cleaner


16


. Here, blower connector


102


plugs directly into socket


82


, and electrical supply


30


delivers power voltage to blower


12


and transformer


104


by way of wires


84


, connectors


82


and


102


, and wires


90


and


92


.




The embodiment of

FIG. 5

is similar to that of

FIG. 3

; however, wire nuts


86


are eliminated by combining wires


84


and


88


(

FIG. 3

) to create a continuous power cord


88


′ that directly couples air cleaner


16


to socket


82


. To power air cleaner


16


and blower


12


, power supply


30


is connected to socket


62


, which, in turn, is coupled to air cleaner socket


82


and blower plug


102


by way of three-way connector


10


.




Although the invention is described with respect to a preferred embodiment, various modifications thereto will be apparent to those skilled in the art. For example, plugs


74


,


78


and


102


could be sockets when sockets


62


,


76


and


82


are plugs. Therefore, the scope of the invention is to be determined by reference to the claims, which follow.



Claims
  • 1. An air handler, comprising:an electric heater; an electric air cleaner; a blower; a first plug-in connector electrically coupled to said electric heater; a second plug-in connector electrically coupled to said electric air cleaner; a third plug-in connector electrically coupled to said blower, said third plug-in connector being selectively coupleable to said first plug-in connector and said second plug-in connector, thereby rendering said air handler selectively reconfigureable; and a three-way connector that includes a fourth plug-in connector, a fifth plug-in connector and a sixth plug-in connector, wherein said fourth plug-in connector is coupleable to said first plug-in connector, said fifth plug-in connector is coupleable to said second plug-in connector, and said third plug-in connector is selectively coupleable to said first plug-in connector, said second plug-in connector and said sixth plug-in connector.
  • 2. The air handler of claim 1, wherein at least one of said fourth plug-in connector, said fifth plug-in connector and said fifth plug-in connector is a plug, and at least one of said fourth plug-in connector, said fifth plug-in connector and said fifth plug-in connector is a socket.
  • 3. The air handler of claim 1, wherein of said electric heater, said electric air cleaner, and said blower, at least one is powered by a primary current and at least one is controlled by a control current, wherein said primary current is supplied at a substantially higher voltage than that of said control current, and wherein said three-way plug-in connector is connected to convey both said primary current and said control current.
  • 4. The air handler of claim 1, further comprising a pair of current interrupters connected electrically in series with said electric heater and electrically in series with said electric air cleaner, wherein said electric heater and said electric air cleaner are connected electrically in parallel with each other.
  • 5. An air handler, comprising:an electric heater; an electric air cleaner; a blower; a first plug-in connector electrically coupled to said electric heater; a second plug-in connector electrically coupled to said electric air cleaner; a third plug-in connector electrically coupled to said blower; and a three-way connector that includes a fourth plug-in connector, a fifth plug-in connector and a sixth plug-in connector, wherein said fourth plug-in connector is coupleable to said first plug-in connector, said fifth plug-in connector is coupleable to said second plug-in connector, and said third plug-in connector is selectively coupleable to said first plug-in connector, said second plug-in connector and said sixth plug-in connector, thereby rendering said air handler selectively reconfigureable.
  • 6. The air handler of claim 5, wherein at least one of said fourth plug-in connector, said fifth plug-in connector and said fifth plug-in connector is a plug, and at least one of said fourth plug-in connector, said fifth plug-in connector and said fifth plug-in connector is a socket.
  • 7. The air handler of claim 5, wherein of said electric heater, said electric air cleaner, and said blower, at least one is powered by a primary current and at least one is controlled by a control current, wherein said primary current is supplied at a substantially higher voltage than that of said control current, and wherein said three-way plug-in connector is connected to convey both said primary current and said control current.
  • 8. The air handler of claim 5, further comprising a pair of current interrupters connected electrically in series with said electric heater and electrically in series with said electric air cleaner, wherein said electric heater and said electric air cleaner are connected electrically in parallel with each other.
  • 9. An air handler for conditioning an airflow, comprising:a first electric heater of a first wattage; a first pair of current interrupters; a first plurality of wires of a first gage connecting said first electric heater electrically in series with said first pair of current interrupters; a second electric heater; a second pair of current interrupters connected electrically in series with said second electric heater; said second electric heater and said second pair of current interrupters being connected electrically in parallel with said first electric heater and said first pair of current interrupters; an electric air cleaner that with respect to said airflow is disposed upstream of said first electric heater and said second electric heater, said electric air cleaner being of a second wattage that is less than said first wattage; and a second plurality of wires of a second gage connecting said electric air cleaner electrically in parallel with said first electric heater and electrically in series with said first pair of current interrupters, said second gage being greater than said first gage, whereby said second plurality of wires has a lower current carrying capacity than that of said first plurality of wires, yet both said first plurality of wires and said second plurality of wires are protected by said first pair of current interrupters.
  • 10. The air handler of claim 9, wherein said blower is connected electrically in parallel with said first electric heater and said electric air cleaner.
  • 11. The air handler of claim 10, further comprising a first plug-in connector electrically coupled to said electric heater;a second plug-in connector electrically coupled to said electric air cleaner; a third plug-in connector electrically coupled to said blower; and a three-way connector that includes a fourth plug-in connector coupled to said first plug-in connector, a fifth plug-in connector coupled to said second plug-in connector, and a sixth plug-in connector coupled to said third plug-in connector.
  • 12. The air handler of claim 11, wherein at least one of said fourth plug-in connector, said fifth plug-in connector and said fifth plug-in connector is a plug, and at least one of said fourth plug-in connector, said fifth plug-in connector and said fifth plug-in connector is a socket.
  • 13. The air handler of claim 11, wherein of said electric heater, said electric air cleaner, and said blower, at least one is powered by a primary current and at least one is controlled by a control current, wherein said primary current is supplied at a substantially higher voltage than that of said control current, and wherein said three-way plug-in connector is connected to convey both said primary current and said control current.
  • 14. A method of reconfiguring an air handler that includes a blower plug-in connector and at least one of a heater plug-in connector and an accessory plug-in connector, comprising: attaching said blower plug-in connector directly to said accessory plug-in connector if said heater plug-in connector is absent; and attaching said blower plug-in connector directly to said heater plug-in connector if said accessory plug-in connector is absent.
  • 15. The method of claim 14, further comprising:attaching said blower plug-in connector directly to a three-way connector, if both said heater plug-in connector and said accessory plug-in connector are present; attaching said heater plug-in connector to said three-way connector; and attaching said accessory plug-in connector to said three-way connector.
US Referenced Citations (5)
Number Name Date Kind
2628083 Rense Feb 1953 A
3260442 Laing Jul 1966 A
4737616 Wen-Ying Apr 1988 A
5133042 Pelonis Jul 1992 A
5259062 Pelonis Nov 1993 A
Foreign Referenced Citations (2)
Number Date Country
2757011 Jul 1979 DE
2578961 Sep 1986 FR